Vaporizers

Question 1

What is vaporization

Answer 1

• converting a liquid to a gas

Question 2

What does volatility mean?

Answer 2

-the ability of a substance to break it’s intermolecular forces

Question 3

Why do we call our inhaled agents volatile agents?

Answer 3

• liquids are converted to vapor to be inhaled by patient and provide general anesthesia

Question 4

What is the goal of the vaporizer

Answer 4

1) convert liquid to vapor at a consistent concentration with
2) tight control

so that we can deliver anesthesia safely (no underdosing or overdosing)

Question 5

Vaporization is dependent on what three things?

Answer 5

• vapor pressure of each volatile agent
• temperature of the ambient environment (linear)
• amount of carrier gas (FGF) increase in flows increase dilution (linear)

Question 6

What gas laws apply to vaporization

Answer 6

• Ideal Gas Law

- Dalton’s Law of Partial Pressure

Question 7

Describe the process of vaporization. How do the components of the Ideal Gas Law relate to vaporization?

Answer 7

• in a sealed container gas molecules crash into the walls and exert a pressure
• that pressure is:
• directly proportional to the number of moles of gas molecules present
• directly proportional temperature of the system
• inversely proportional is volume

Question 8

Dalton’s Law of Partial Pressure

Answer 8

-total pressure in a given space is calculated by adding the partial pressures of each gas

Question 9

How is vapor pressure calculated from total pressure?

How is concentration calculated from vapor pressure?

Answer 9

• (molar fraction)(total pressure) = (vapor pressure)

- vapor pressure/barometric pressure = concentration or molar fraction

Question 10

What is concentration measured in?

Answer 10

V/V %

Question 11

Enflurane Vapor Pressure

Answer 11

172 mmHg

Question 12

Isoflurane Vapor Pressure

Answer 12

240 mmHg

Question 13

Halothane Vapor Pressure

Answer 13

244 mmHg

Question 14

Sevoflurane

Answer 14

157 mmHg

Question 15

Desflurane Vapor Pressure

Answer 15

669 mmHg

Question 16

When anesthesia providers select a dose of volatile agent that the vaporizer will deliver they select what?

Answer 16

• v/v %

- partial pressure of gas / total atmospheric pressure x 100

Question 17

What is the partial pressure of oxygen, nitrogen, and other at atmospheric temp?

Answer 17

• Oxygen = .21 x 760 = 160
• Nitrogen = .779 x 760 = 592
• Other = .011 x 760 = 8.4

Question 18

What effect does temperature have on the vaporization process?

Answer 18

-(direct) as temperature decreases, vapor pressure decreases

Question 19

What is the latent heat heat of vaporization?

Answer 19

• the energy (calories or joules) at which a liquid or volatile anesthetic changes from a liquid to a gas without changing its temperature

Question 20

Why is there no change in temperature?

Answer 20

There is no temperature change because although you are adding energy to the liquid, energy is escaping in the form of kinetic energy once the molecules at the surface leave in the form of gas molecules

Question 21

When the latent heat of vaporization is reached, what effect happens to the liquid

Answer 21

-the remaining liquid will be depleted of its energy, having a cooling effect, decreasing vapor pressure

Question 22

Why is the liquid cooling a problem?

Answer 22

Decrease in vapor pressure means decrease in anesthetic concentration means under-dose

Question 23

How do you prevent the cooling of liquid

Answer 23

-add a constant heat source

Question 24

Liquid and vapor are _____ at vapor pressure

Answer 24

Equilibrium

Question 25

Adding heat source shift equilibrium toward _____

at this time vapor pressure is ________

Answer 25

(Right) toward vapor

Increases

Question 26

Adding cooling source shift equilibrium toward _____

at this time vapor pressure is ________

Answer 26

(Left) liquid

Decreasing

Question 27

Adding blow by gas shift equilibrium toward _____

at this time vapor pressure is ________

Answer 27

(Right) vapor

Decreased or constant

Question 28

Specific heat

Answer 28

• the amount of energy required to increase the temperature of a specific volume of substance by 1 degree centigrade

Question 29

Vaporizers are made with materials with a ______ specific heat. Why?

Answer 29

High

- resists changes in temperature so resists evaporative cooling and delivers gas at a more constant concentration

Question 30

Thermal conductivity

Answer 30

-measures the speed at which heat flows through something; higher thermal conductivity the better the substance conducts heat

Question 31

Vaporizers are produced with materials with _____ thermal conductivity, why?

Answer 31

High

-to maintain a consistent temperature within the vaporizer

Question 32

What effect does altitude have on the barometric pressure?

Answer 32

(Inverse)

• as altitude increases, barometric pressure decreases
• as altitude decreases, barometric pressure increases

Question 33

Types of vaporizers

Answer 33

• variable bypass
• tech 6
• cassette
• injection

Question 34

How does a Variable bypass vaporizer work? How is it compensated?

Answer 34

• has a bypass chamber and vaporizing chamber
• portion of gas goes to vaporizing chamber to be saturated; another portion goes through the bypass chamber
• a variable orifice at the inlet controls gas flow
• vapor laden portion meets bypass portion to be diluted and delivered.
• agent specific, temp pressure compensated

-this device uses:
pressure compensation mechanism
temperature compensation mechanism
split ratio to deliver a safe, consistent anesthetic vapor

Question 35

Pressure compensation mechanism

Answer 35

• prevents major overdose
• detects “pumping” or retrograde pressure in the system
• does not allow it to create retrograde flow of gas into the bypass chamber

Question 36

Temperature compensation mechanism

Answer 36

• prevents major underdose
• metal that expands/shrinks in response to evaporative cooling
• proportions the bypass chamber flow to the vaporizing chamber flow

Question 37

What two mechanisms control the concentration of volatile agent through the outlet

Answer 37

1) temperature compensation mechanism

2) concentration control dial

Question 38

What temperatures does the temperature compensating mechanism work in?

Answer 38

50-104 degrees F

10 - 40

Question 39

Factors that impact vaporizer output

Answer 39

• extreme flow rates = underdose
• temperature at boiling points
• pumping effect = overdose
• carrier gas composition (not clinically relevant)
• barometric pressure = under/over

Question 40

How do extreme flow rates affect concentration of volatile anesthestic

Answer 40

-if you administer really high flow (>15L/min), and really low flow (<125mL/min) your v/v% may be slightly less than what you dialed in

Question 41

How does temperature at boiling point affect volatile anesthetic concentration?

Answer 41

-at the boiling point the volatile agent is moving into a gas too quickly, there is no control over it’s flow (~50 degrees C)

Question 42

How does the pumping effect affect volatile anesthetic concentration?

Answer 42

-this will result in a back flow of anesthetic vapor into the main inflow line increasing the concentration overall, resulting in massive overdose

Question 43

How does carrier gas composition effect the volatile agent concentration?

Answer 43

-if you add nitrous as carrier gas instead of oxygen, it is a little more soluable in liquid so it can increase concentrations

Question 44

How does barometric pressure affect the volatile anesthetic concentration?

Answer 44

At higher altitudes and lower barometric pressure, the partial pressure of the volatile agent will be a greater percentage of the barometric pressure.

Question 45

What are some potential vaporizer hazards?

Answer 45

• wrong agent wrong vaporizer (high VP gas in low VP container = overdose + hypoxemic mixture; low VP gas in high VP container = underdose)
• contamination (can cause bacterial growth)
• tipping (overdose)
• overfilling (overdose)
• leaks (underdose)
• pumping effect (overdose)

Question 46

In high altitudes do you have to make changes to a variable bypass vaporizer? Do you make changes in a tech 6?

Answer 46

• no changes with variable bypass

- changes with tech 6

Question 47

Why do we need a Tech6 to give Des?

Answer 47

• VP 669 (87%) at 1atm so need HIGH FGF to dilute des (not economic)
• Des not very potent, requires MAC of 6.6% so has very fast evaporative cooling and requires constant heat source
• Des boiling point 73 degrees at 1atm; will quickly boil and lose control of output

Question 48

Tech 6 vaporizer

Answer 48

• electrically heated
• pressurized
• “dual gas” blender two independent gas circuits in parallel

Question 49

What two variables impact tech 6 vaporizer output?

Answer 49

1) Altitude: you have to deliver higher dialed desflurane than at sea level;
- (desired % at sea level)(760mmHg)/ (current barometric pressure)
Carrier gas: vaporizer calibrated to 100% oxygen
- lower O2 concentrations than 100% or nitrous as carrier gas can decrease output by 20%

Question 50

Aladin Cassette Vaporizers

used at georgetown

Answer 50

• electronicallly controlled variable bypass unit in which the bypass circuit is within the anesthesia machine and the vaporizing chamber and circuit are within the cassette
• color coded and magnetically coded for safety
• some have warming fans that warm arm to decrease evaporative cooling effect

Question 51

Desflurane = ____

Answer 51

Blue

Question 52

Isoflurane = _____

Answer 52

Purple

Question 53

Sevoflurane = _____

Answer 53

Yellow

Question 54

What does the check valve do in a cassette vaporizer

Answer 54

-prevents against overdose by preventing retrograde pressure from O2 flush or retrograde flow by tipping etc.

Question 55

From what area does the CPU in the cassette vaporizer gather data

Answer 55

• pressure and temperature sensors in the vaporizing chamber
• flowmeters in the bypass chamber and vaporizing chamber
• control dial set by the provider

Question 56

How does the CPU affect outflow of gas

Answer 56

-CPU will use the flow control valve to determine the amount of flow leaving the vaporizing chamber, dictating the percent of fresh gas saturated with volatile anesthetic at the outflow

Question 57

Safety mechanisms of the cassette vaporizer

Answer 57

• electronic control of the carrier gas ratio
• safety relief valve
• when cassette removed from machine, valves close to prevent FGF loss
• spill valve

Question 58

-Electronic control of carrier gas ratio

Answer 58

-prevents hypoxemic gas mixture

Question 59

Safety relief valve

Answer 59

-detects obstruction in system; cassette pressure up 2.5atm; valve opens

if desfluane boils; valve open up and allows pressure to escape into atm;

Question 60

Closing valves

Answer 60

-allows you to change cassettes during case

Question 61

Spill valve

Answer 61

• prevents retrograde flow from tipping overfilling

Question 62

What happens in the desflurane cassette when desflurane boils?

Answer 62

• when OR temp is higher than 73 degrees and pressure becomes higher in vaporizer chamber than bypass chamber, the one way check valve closes and does not allow any FGF into vaporizing chamber; CPU starts to inject desflurane

Question 63

What types of vaporizers does the Desflurane cassette function as?

Answer 63

• variable bypass until boiling
• switches to injector
• controlled by CPU

Question 64

Injector Vaporizer

Answer 64

• agent specific
• electronically controlled
• vaporizer output set by electronic interface on anesthesia machine
• gas enters via drive gas inlet, pressurized liquid, moving it to injector
• liquid injected into heat vaporizing chamber and monitored by microprocessor
• injections continue in small amounts until desired volume is reached
• gas analyzer downstream measures output
• optical sensor in the chamber monitors integrity of injections